Modeling Dark Sector in Horndeski Gravity at First-Order Formalism

Santos, Fabiano F.; Neves, R. M.; Brito, F. A.

doi:10.1155/2019/3486805

Cited by 7 publications

(3 citation statements)

References 51 publications

(71 reference statements)

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“…It is interesting to note that the above toy model can be extended in the presence of boundaries within a special case of the Horndeski gravity, [18] (see for example, refs. [19][20][21][22][23][24][25][26]). Here, the gravity theory is given through the Lagrangian…”

Section: Introductionmentioning

confidence: 99%

AdS/BCFT Correspondence and Horndeski Gravity in the Presence of Gauge Fields: Holographic Paramagnetism/Ferromagnetism Phase Transition

Santos,

Bravo‐Gaete,

Sokoliuk

et al. 2023

Fortschritte der Physik

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This paper presents a dual gravity model for a (2+1)‐dimensional system with a limit on finite charge density and temperature, which will be used to study the properties of the holographic phase transition to paramagnetism‐ferromagnetism in the presence of Horndeski gravity terms. In our model, the non‐zero charge density is supported by a magnetic field. As a result, the radius indicates a localized condensate, as the Horndeski gravity parameter is increased, that is represented by γ. Furthermore, such condensate shows quantum Hall‐type behavior. This radius is also inversely related to the total action coefficients of our model. It is observed that increasing the Horndeski parameter decreases the critical temperature of the holographic model and leads to the harder formation of the magnetic moment at the bottom of the black hole. However, when removing the magnetic field, the ferromagnetic material presents a disorder of its magnetic moments, which is observed through the entropy of the system. The authors also found that at low temperatures, spontaneous magnetization and ferromagnetic phase transition.

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Section: Introductionmentioning

confidence: 99%

AdS/BCFT Correspondence and Horndeski Gravity in the Presence of Gauge Fields: Holographic Paramagnetism/Ferromagnetism Phase Transition

Santos,

Bravo‐Gaete,

Sokoliuk

et al. 2023

Fortschritte der Physik

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show abstract

“…This background has already been shown to encode many interesting condensed-matter-like phenomena such as superconductivity/superfluidity [15,16] and strange metallic behaviors [17], via an action characterized by the well-known Einstein-Hilbert structure together with a cosmological constant and Abelian gauge fields. It is interesting to note that the above toy model can be extended in the presence of boundaries within a special case of the Horndeski gravity [18], (see for example [19][20][21][22][23][24][25][26]). Here, the gravity theory is given through the Lagrangian…”

Section: Introductionmentioning

confidence: 99%

AdS/BCFT correspondence and Horndeski gravity in the presence of gauge fields: from holographic paramagnetism/ferromagnetism phase transition

Santos¹,

Bravo‐Gaete²,

Sokoliuk³

et al. 2023

Preprint

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This paper presents a dual gravity model for a (2+1)-dimensional system with a limit on finite charge density and temperature, which will be used to study the properties of the holographic phase transition to paramagnetism-ferromagnetism in the presence of Horndeski gravity terms. In our model, the non-zero charge density is supported by a magnetic field.As a result, the radius ρ/B indicates a localized condensate, as we increase the Horndeski gravity parameter, that is represented by γ. Furthermore, such condensate shows quantum Hall-type behavior. This radius is also inversely related to the total action coefficients of our model. It was observed that increasing the Horndeski parameter decreases the critical temperature of the holographic model and leads to the harder formation of the magnetic moment at the bottom of the black hole. However, when removing the magnetic field, the ferromagnetic material presents a disorder of its magnetic moments, which is observed through the entropy of the system. We also found that at low temperatures, spontaneous magnetization and ferromagnetic phase transition.

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“…In this context, Horndeski gravity presents itself to be one of the most general of such theories evading instabilities of the Ostrogradsky type [37]. The theory has been extensively tested in cluster lensing experiments [38], CMB data [39,40], etc and widely studied in the context of cosmology [41][42][43][44][45]. However, on the question of its verification using LIGO data [46][47][48][49][50][51][52], some recent works do restrict some parameters of the theory using the event GW170817 [53,54].…”

Section: Introductionmentioning

confidence: 99%

A study of eccentric binaries in Horndeski theory

Chowdhuri¹,

Bhattacharyya²

2022

Preprint

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We study the orbital evolution of eccentric binary systems in Horndeski theory. This particular theory provides a testbed to give insightful comparisons with data. We compute the rate of energy loss and the rate of change of angular momentum for the binaries by calculating the multipole moments of the radiation fields. We have used appropriate parameters for the eccentric binaries to compute the decay rates of its orbital eccentricity and semi-major axis. We then compare this decay rate with that of GR.

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Modeling Dark Sector in Horndeski Gravity at First-Order Formalism

Cited by 7 publications

References 51 publications

AdS/BCFT Correspondence and Horndeski Gravity in the Presence of Gauge Fields: Holographic Paramagnetism/Ferromagnetism Phase Transition

AdS/BCFT Correspondence and Horndeski Gravity in the Presence of Gauge Fields: Holographic Paramagnetism/Ferromagnetism Phase Transition

AdS/BCFT correspondence and Horndeski gravity in the presence of gauge fields: from holographic paramagnetism/ferromagnetism phase transition

A study of eccentric binaries in Horndeski theory

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